Journal of Microbiology, Biotechnology and Mohammed and Horniakova 2012 : 1 (6) 1462-1475 Food Sciences
1462
REGULAR ARTICLE
REFLECT OF UTILIZATION DIFFERENT LIPIDS LEVEL ON AMINO AND
FATTY ACIDS PROFILE OF BROILER’S (ROSS-308) LIVER
Hasan Abdullah Mohammed1, Erika Horniaková2
Address*: Msc Hasan Abdullah Mohammed, doc.Ing.Erika Horniakova PhD; Slovak
University of Agriculture, Faculty of Agrobiology and food resources, Department of Animal
Nutrition Processing: 1Tr.A.Hlinku 1200/38 Nitra, Slovak republic, 2Tr.A.Hlinku2.949.76 Nitra, Slovak republic, email ([email protected])
*Corresponding author: [email protected]
ABSTRACT
In this work we investigated the effect of utilization two type of fat, saturated fat(SF)
representative by animal fat as a 5% packed fat (PF) in control group (C) and unsturated
fat(USF) repecentive by2.5% sunflower oil (SUN) mixed with 2.5% PF as treatment1(T1),
another USF 2.5% of rapeseed oil (RO) is used mixed with 2.5%PF as treatment 2 (T2) and
last treatment (T3) is mixed 2.5% PF+1.25 SUN+1.25 RO. Insignificat diffrences (P>0.01)
for all amino acids except cystine wassignificant (P<0.01) and high value found in C group
(15.42). High value of tosal SF found in C group (44.82%).
Keywords: Broiler (Ross-308), Amino and Fatty Acids, liver profile and human health
INTRODUCTION
A major reason for the current interest in dietary fat is related to the evidence of
linking high fat intakes, especially saturated fats, to coronary heart disease (CHD). High
levels of blood cholesterol, in particular LDL cholesterol, constitute a major risk factor in
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CHD. Interest in dietary fat and CHD was centred primarily on saturated and polyunsaturated
fatty acids until 1985, when Mattson and Grundy (1985) reported, that monounsaturated
fatty acids, namely oleic acid, were as effective as PUFA in reducing plasma total and LDL
cholesterol levels. These observations coincided with the relatively low incidence of CHD
observed among populations consuming the so-called Mediterranean diet, which is
characterized by a high intake of fat but primarily from olive oil. The prevailing theory at the
time argued, that saturated fatty acids raised blood cholesterol, PUFA lowered blood
cholesterol and MUFAs were neutral, they neither raised nor lowered blood cholesterol
(Abdel-Hakim et al., 1982). The demonstration showed that vegetable oils with high
concentration in oleic acid were effective in reducing blood cholesterol (Vilchez et al., 1991).
Transfatty acids are produced, when fats and oils are hydrogenated (hardened) for use in the
manufacture of margarines and derivative. The report by Mensink and Katan (1990) that
high intakes of trans fatty acids not only increased plasma LDL cholesterol levels, but
lowered plasma high density lipoprotein (HDL) cholesterol levels, triggered an intense debate
on the physiological effects of hydrogenated fats, particularly in relation to CHD. The study
also brought into question the wisdom of replacing saturated fats with hydrogenated products.
At studies with an experimental (rat) model, McLennan et al. (1988) have shown,
that diets enriched in long chain omega-3 fatty acids (viz., eicospentaenoic acid EPA and
docosahexaenoic acid (DHA) protected against induced arrhythmias. Sunflower oil, a rich
source of omega-6 fatty acids, also provided partial protection against induced arrhythmias in
the rat model. Likewise, arrhythmic effects were observed when experimental animals were
fed diets containing canola oil (McLennan and Dallimore, 1995). By contrast, feeding diets
containing olive oil, soybean oil and sunflower oil did not significantly decrease the incidence
of induced cardiac arrhythmia in the experimental animals in this study. These findings
suggest that the balance between the dietary omega-3 and omega-6 fatty acid content may be
important, because the soybean oil diet provided essentially the same level of α-linolenic acid
as the canola oil diet, but 2.5 times as much linoleic acid. Overall, all for amino acids (AA)
diets yielded high-quality breast and thigh meat, whereas the high amino acids diet yielded
broilers with excellent live performance, carcass traits, and meat quality.
The objective of our study was to find influence of diet include different type of lipid
on liver content for fatty and amino acids which also reflect on human health.
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MATERIAL AND METHODS
Experimental material and conditions
The experiment was realized at the test station poultry of Slovak Agricultural University
in Vígľaš; research farm in Kolíňay. on feeding of Ross-308 chicken hybrid combination.
The experiment enrolled 800 pieces of one day chickens hybrid combination and were created
4 groups of animals: control (C) and three experimental (I, II and III) of 50 pcs of chickens.
Custom feeding insisted 42 days. Chickens are housed in the experimental procedure under
the same technological conditions. Viewed climatic variables must meet the criteria for the
type and category of animals. Other technology systems (ventilation, lighting intensity, length
of day light) implemented as recommended by the fattening technology applicable to a
particular hybrid chicken included in the experiment.
The feed formulation and feeding periods
Isocaloric and isonitrogenous diets formulated by the use of the program (G7 2000)
are based on least cost design.
Experimental intervention
The fat added to complete feed mixtures manufacturer in different concentration at all
the groups, group one (C) 5% animal fat under name commercial packed fat, group two (T1)
2 .5% packed fat + 2 .5% Sunflower oil, group three (T2) 2.5% packed fat +2.5% rapeseed
oiland group four was 2.5%packed fat +1.25 sunflower oil -1.25 rapeseedoil In 800 Broiler
line Ross308. Periods of breeding was 0-7 days for prestarter, 8-17 days for starter, 18-34 for
grower, 35-41 for finisher and at 42 days were slaughtered. The laboratory analysis as
performed done in Animal Nutrition Department of Slovakia Agriculture University.
Determination of Amino acids
Poultry have a nutritional requirement not for total protein, but rather for essential
amino acids that are contained in their dietary crude protein (Wiseman et al., 1991). Ion
exchange chromatography method used and amino acid analyzer (AAA 400 by INGOS,
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Pragh, Czech R.) applied for determination total amino acids. ISO 13903 (2005) standard
method was applied. The brief procedure of AAs analysis practiced after made leufilization.
Calculation of results
The area of the sample and standard peaks is measured for each individual amino acid
and the amount, in g amino acid per kg sample, is calculated.
g amino acid per kg sample= ( A × E × MW × F ) / B × W × 1000
A = peak area, hydrolysate or extract
B = peak area, calibration standard solution
MW= molecular weight of the amino acid being determined
E = concentration of standard in lmol.ml-1
F= ml total hydrolyzed or ml calculated total dilution volume of extract.
W = sample weight (g) (corrected to original weight if dried or defatted)
Cystine and cysteine are both determined as cysteic acid in hydrolysates of oxidized
sample, but calculated as cystine (C6H12N2O4S2, MW 240.30 by using MW 120.15 (= 0.5×
240.30). Methionine is determined as methionine sulphone in hydrolysates of oxidized
sample, but calculated as methionine by using MW of methionine: 149.21. Table1,2,3and 4
observed typs of amino acids inclued of diet in diffrent period breeding.
Table 1 Amino acid composition of experimental diets at pre-starter period
AA /g/kg// number of
sample
Groups
C T1 T2 T3
Aspartic acid 24.5471 24.0951 24.6929 23.7873
Threonine 9.6072 9.4471 9.5495 9.3289
Serine 12.1335 11.7077 11.5835 11.4010
Glutamic acid 42.4640 41.8444 42.4193 41.1279
Proline 15.7576 15.6834 15.7383 15.2599
Glycine 10.7657 10.5844 10.9076 10.5402
Alanine 11.5427 11.3523 11.6334 11.2666
Valine 11.7977 11.8218 12.4688 11.9335
Isoleucine 10.4194 10.3590 10.7867 10.4705
Leucine 20.1486 19.6991 20.1239 19.5414
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Tyrosine 8.2989 7.9666 8.0627 7.6588
Phenylalanine 11.9520 11.6006 12.0229 11.3083
Histidine 6.9640 7.0376 7.1589 6.8313
Lysine 15.3967 15.2052 15.6159 15.0999
Arginine 18.9042 18.5267 19.1471 18.7073
Cystine 4.8720 4.8328 4.9510 4.8203
Methionine 8.1528 8.4175 7.9896 8.1988
Sum of amino acids
/g/kg/
243.7241 240.1813 244.8520 237.2819
Nitrogen compounds % 26.39 25.71 26.01 25.84
Dry matter % 100.00 100.00 100.00 100.00
Table 2 Amino acid composition of experimental diets at starter period
AA /g/kg// number of sample
Groups C T1 T2 T3
Aspartic acid 21.9315 21.7423 22.4633 21.7657 Threonine 8.6535 8.5682 8.5954 8.4456 Serine 11.1141 10.7663 11.1300 10.9280 Glutamic acid 38.7459 37.6346 39.5115 39.4864 Proline 14.6884 14.3658 14.3819 15.0480 Glycine 9.7056 9.9081 9.7844 9.9529 Alanine 10.6366 10.8248 10.5520 10.9475 Valine 10.3165 10.3926 10.7814 11.0031 Isoleucine 8.9867 8.9526 9.3002 9.4500 Leucine 18.1650 17.7596 17.6074 18.2793 Tyrosine 7.4586 7.1670 7.2008 7.4014 Phenylalanine 10.7053 10.3702 10.6981 10.6664 Histidine 6.4783 6.4209 6.5998 6.3889 Lysine 13.8183 14.3105 13.9910 14.0663 Arginine 17.0039 16.6456 17.1946 17.3692 Cystine 4.8869 4.4389 4.7948 4.6403 Methionine 7.7064 8.0018 7.3195 7.3728 Sum of amino acids /g/kg 221.0017 218.2698 221.9061 223.2117 Nitrogen compounds % 24.41 23.83 24.22 24.32 Dry matter % 100.00 100.00 100.00 100.00
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Table 3 Amino acid composition of experimental diets at grower period
AA /g/kg// number of
sample
Groups
C T1 T2 T3
Aspartic acid 18.9196 19.9725 19.1730 20.0445
Threonine 7.2279 7.5950 7.2885 7.8521
Serine 9.4062 10.1362 9.9514 10.3714
Glutamic acid 36.1336 38.5740 36.3258 37.7272
Proline 13.4662 14.7115 13.7663 14.6419
Glycine 8.1069 8.2875 8.0711 8.5442
Alanine 8.9546 8.8899 8.5821 9.7122
Valine 9.5198 9.7194 8.6623 9.2000
Isoleucine 8.3211 8.7468 7.6103 7.9081
Leucine 15.9665 16.5400 15.8410 16.3266
Tyrosine 6.4714 6.0743 6.2704 6.3297
Phenylalanine 9.6246 9.1545 9.2991 9.5772
Histidine 5.3940 5.6948 5.6539 5.7482
Lysine 11.5903 11.8800 11.3901 11.9752
Arginine 15.1807 15.7846 14.1481 15.3788
Cystine 4.4644 4.7923 4.5530 4.4974
Methionine 6.2250 6.6193 6.2470 6.1119
Sum of amino acids /g/kg/ 194.9727 203.1728 192.8335 201.9464
Nitrogen compounds 21.32 22.11 21.41 21.56
Dry matter % 100.00 100.00 100.00 100.00
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Table 4 Amino acid composition of experimental diets at finisher period
AA /g/kg// number of
sample
Groups
C T1 T2 T3
Aspartic acid 16.6571 16.4708 16.5219 16.5773
Threonine 6.9652 6.7473 6.7330 6.7211
Serine 9.3304 8.9485 8.8372 9.1095
Glutamic acid 36.5100 35.7464 36.1464 36.6481
Proline 14.2009 13.7724 14.3342 14.5686
Glycine 7.4823 7.4214 7.4387 7.4271
Alanine 7.6911 7.9591 8.1014 7.8677
Valine 8.4633 8.4441 8.4977 8.4884
Isoleucine 7.2528 7.1176 7.2370 7.2309
Leucine 14.7320 14.3242 14.6560 14.8095
Tyrosine 5.6940 5.5822 5.7593 5.6766
Phenylalanine 8.6121 8.6267 8.9097 8.7093
Histidine 5.0525 4.9717 5.1111 5.1037
Lysine 10.6475 10.4465 10.6717 10.5498
Arginine 13.2775 12.8388 13.1952 13.2917
Cystine 4.3893 4.3717 4.3626 4.3323
Methionine 6.6069 6.8336 7.0821 6.6953
Sum of amino acids /g/kg/ 183.5649 180.6229 183.5953 183.8068
Nitrogen compounds /% / 19.83 19.98 19.73 19.87
Dry matter /%/ 100.00 100.00 100.00 100.00
Determination of Crude Fat and Fatty Acids Methyl Esters (FAME)
Total fat content of meat and liver was determined by application of ISO- 11085
(2008) standard method. Fatty acids analysis was prepared by modification method of ISO/
TS 17764-1 (2002). Table 5 and 6 observed inclued of fatty acids composion in diet of
diffrent periods breedind.
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Table 5 Fatty acid composition of diets during pre-starter and starter periods
Fatty Acids
Groups
C T1 T2 T3
% of Crud Fat in Pre-starter Period
Lauric / C12: 0 0.12±005 b 0.11±0.01b 0.12±0.01b 0.08±0.003a
Myristic/C14:0 1.04±0.01c 0.77±0.01b 0.99±0.02b 1.01±0.01b
Palmatic/C16:0 38.03±0.30c 34.88±0.44b 36.12±0.81bc 30.14±1.70 a
Palmitolic/C16:7 8.27±0.28 a 10.97±0.10b 8.66±0.67 a 9.13±0.51 a
Steric/C18:9 42.31±0.22b 14.24±0.64a 42.38±0.17b 42.00±0.09b
Oleic/C18:9 8.51±0.17 a 11.16±0.94b 9.29±0.29 a 8.96±0.69 a
Linolic/C18:6 17.43±2.01 14.72±0.12 16.83±1.72 17.57±0.46
Linolenic/ C18:6,9 0.02±0.01 a 0.10±0.01 a 0.75±0.08b 0.80±0.04b
Arachidic/C20:0 0.47±0.03 0.51±0.01 0.57±0.15 0.52±0.01
Arachidonic/C20:5,8,11,14 0.10±0.01 b 0.09±0.01 b 0.06±0.02 b 0.001±0.04a
Behenic/C22:0 0.92±0.01b 0.97±0.04b 0.85±0.03a 0.85±0.03a
% of Crud Fat in starter Period
Lauric / C12: 0 0.16±0.004b 0.14±0.01b 0.15±0.01b 0.11±0.003a
Myristic/C14:0 0.96±0.01c 0.68±0.01b 0.90±0.02bc 0.92±0.01a
Palmatic/C16:0 29.45±0.30 c 26.30±0.44b 27.53±0.81bc 21.55±1.70 a
Palmitolic/C16:7 8.58±0.28 a 11.26±0.10b 8.96±0.67 a 9.43±0.51 a
Steric/C18:9 26.69±0.22b 25.62±0.64a 26.73±0.17b 26.38±0.09b
Oleic/C18:9 17.77±0.17a 20.42±0.94b 18.54±0.29a 18.22±0.69a
Linolic/C18:6 32.78±2.01 30.07±0.12 32.18±1.71 32.92±0.46
Linolenic/ C18:6,9 0.52±0.004a 0.59±0.01 a 1.24±0.08 b 1.29±0.04 b
Arachidic/C20:0 0.38±0.03 0.42±0.005 0.50±0.19 0.44±0.005
Arachidonic/C20:5,8,11,14 0.12±0.005b 0.11±0.005b 0.08±0.03 b 0.03±0.03 a
Behenic/C22:0 0.35±0.01b 0.40±0.03b 0.29±0.03a 0.24±0.02a
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Table 6 Fatty acid composition of diets during grower and finisher periods
Fatty Acids
Groups
C T1 T2 T3
% of Crud Fat in grower Period
Lauric / C12: 0 0.11±0.02a 0.12±0.01b 0.12±0.01b 0.09±0.002a
Myristic/C14:0 0.74±0.01c 0.46±0.01a 0.69±0.02b 0.70±0.01b
Palmatic/C16:0 12.44±0.30c 36.29±0.44b 37.53±0.81bc 31.55±1.70a
Palmitolic/C16:7 9.28±0.28a 11.96±0.67b 9.66±0.67a 10.13±0.51a
Steric/C18:9 45.19±0.22b 44.122±0.64a 45.24±0.17b 44.88±0.09b
Oleic/C18:9 7.64±0.17a 10.30±0.94b 8.42±0.29a 8.10±0.69a
Linolic/C18:6 13.10±1.84 11.90±0.12 14.01±1.72 14.75±0.46
Linolenic/ C18:6,9 0.02±0.004a 0.10±0.01a 0.75±0.08b 0.79±0.04b
Arachidic/C20:0 0.49±0.04 0.52±0.005 0.58±0.14 0.54±0.01
Arachidonic/C20:5,8,11,14 0.12±0.03b 0.12±0.01b 0.09±0.03ab 0.04±0.03a
Behenic/C22:0 0.37±0.08ab 0.45±0.04b 0.33±0.03a 0.28±0.02a
% of Crud Fat in finisherPeriod
Lauric / C12: 0 0.16±0.004b 0.14±0.01b 0.15±0.01b 0.11±0.003a
Myristic/C14:0 0.75±0.01c 0.47±0.01a 0.70±0.02b 0.71±0.01b
Palmatic/C16:0 38.47±0.30c 35.32±0.44b 36.56±0.81ab 36.57±1.70a
Palmitolic/C16:7 9.01±0.28a 11.70±0.10b 9.12±0.67a 9.87±0.51a
Steric/C18:9 35.15±5.36 34.97±4.98 35.08±5.20 35.02±5.09
Oleic/C18:9 42.35±0.17a 45.00±0.94b 43.13±0.29a 42.80±0.69a
Linolic/C18:6 17.47±2.01 14.76±0.12 16.87±1.72 17.61±0.46
Linolenic/ C18:6,9 0.03±0.004a 0.11±0.01a 0.76±0.08b 0.80±0.04b
Arachidic/C20:0 0.52±0.03 0.56±0.005 0.52±0.03 0.57±0.005
Arachidonic/C20:5,8,11,14 0.10±0.005b 0.09±0.005b 0.06±0.02b 0.01±0.04a
Behenic/C22:0 0.33±0.005b 0.38±0.04b 0.26±0.03a 0.22±0.02a
Slaughter outputs
The liver was immediately removed from hot carcasses, packed in plastic bags and
stored in liquid nitrogen until the time of analysi (Picture 1).
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Figure 1 Removed of liver immediatly after slaughtering from carcass
Statistical analysis
For the statistical design and data analyses, complete random design an experiment
with 4 treatments were determined. Data in all experiments were subjected to ANOVA
procedures appropriate for a completely randomized design and the significance of
differences between the means estimated using Duncan test (Duncan’s new multiple range
test). Probability level of was Significance in all comparisons with chemical parameters which
P<0.01 was considered. Values in percentage were subjected to transformation of Arc sin
v100. All statistical analyses were performed using the software SPSS 17.5 for Windows®
(SPSS Inc., Chicago, IL).
RESULTS AND DISCUSSION
Effects of diet on amino acid profile of broilers liver
Broiler meat is one of the principal sources to fill the genuine gaps of the animal
protein and can play leading role in providing balanced diet (Alam and Khan, 2000).
Data from Table 7 pointed there were insignificant differences among all treatment
with all of type amino acids expect Cyctine was significant differences (P<0.01) and high
value found in group control (15.42g.kg-1).
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Table 7 Effects of diet on amino acid profile of broilers liver
AA /g/kg// number of
sample
Groups
C T1 T2 T3
Aspartic acid 62.29±3.54 61.59±1.96 62.913±1.69 64.58±0.90
Threonine 32.07±2.40 31.00±1.24 31.47±0.84 32.54±0.58
Serine 31.56±2.72 31.25±1.19 32.82±1.08 33.62±0.50
Glutamic acid 77.44±4.23 75.77±2.64 77.08±1.66 77.37±097
Proline 31.10±4.39 32.72±2.57 31.91±1.39 32.78±0.67
Glycine 34.75±1.34 34.5±3.38 34.37±1.18 33.80±0.67
Alanine 42.70±2.75 42.13±2.43 42.27±1.03 42.99±0.88
Valine 39.64±1.69 37.80±3.98 35.57±0.74 35.57±0.74
Isoleucine 29.62±1.47 28.31±3.31 27.47±0.63 27.81±0.25
Leucine 60.89±2.40 59.09±4.10 59.67±1.19 60.68±0.90
Tyrosine 26.14±1.94 25.88±1.92 24.65±1.15 25.65±1.27
Phenylalanine 34.12±1.86 33.13±1.73 33.24±0.68 34.05±0.32
Histidine 19.33±1.37 18.96±0.79 19.06±0.56 19.21±0.52
Lysine 50.77±2.61 49.41±3.06 48.37±1.18 50.40±0.98
Arginine 45.73±2.85 44.24±2.53 44.80±0.49 44.70±0.49
Cystine 15.42±0.58b 14.70±0.42ab 14.46±0.24ab 13.95±0.66a
Methionine 18.01±0.97 17.34±0.51 16.90±0.07 17.73±0.50 a,b means with different superscript within row are significantly different (P< 0.01) *Values are x̅ ± Std. Deviation of 50 chickens
This can be attributing to function of the liver to conver type of AA from carboxyde
group and make bond with group of amide to synthesis of AA (Hesabi et al., 2008). Therefor
increase the level of AA in liver compare with the level in diet (tables precent 1,2, 3 and 4 ).
This result agree with result of Aletor et al. (2000).
Effect of diets on the fatty acids profile of liver
An increased production of cholesterol and other repair factors in the liver increases
the levels of these molecules in the bloodstream and, over time, renders them risk factors for
cardiovascular disease (Rath, 1993). Table 8 and 9 observed there were insignificant
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differences (P>0.01) for lauric, myristic palmitic, oleic, aracidic, arachidonic and behenic
acids.
Table 8 Effect diets on fatty acid compositions of liver are in experimental broilers
Fatty Acids
Groups
C T1 T2 T3
Fatty acid composition (% of total FA)
Lauric / C12: 0 0.09±0.04 0.13±0.13 0.04±0.03 0.06±0.05
Myristic/C14:0 0.51±0.12 0.45±0.16 0.43±0.12 0.61±0.16
Palmatic/C16:0 30.25±1.26 30.03±0.68 26.85±4.31 26.00±3.08
Palmitolic/C16:7 13.33±1.42b 10.98±1.28b 10.18±2.07a 7.69±0.58a
Steric/C18:9 14.44±0.92b 13.17±0.53ab 11.29±1.37 a 11.14±1.36a
Oleic/C18:9 19.27±2.28 19.39±0.84 18.31±0.53 19.50±1.38
Linolic/C18:6 13.55±0.37c 11.75±1.11bc 9.93±1.02 ab 9.20±0.76 a
Linolenic/ C18:6,9 0.06±0.06a 0.43±0.25b 0.56±0.08b 0.65±0.02b
Arachidic/C20:0 0.06±0.04 0.08±0.01 0.056±0.03 0.06±0.03
Arachidonic/C20:5,8,11,14 0.20±0.02 0.17±0.03 0.23±0.04 0.24±0.04
Behenic/C22:0 0.07±0.01 0.12±0.02 0.07±0.03 0.06±0.04 a,b means with different superscript within row are significantly different (P< 0.01) *Values are x̅ ± Std. Deviation of 50 chickens
Table 9 Calculation of different profiles of the fatty acids in experimental groups of liver’s
Groups Total
SFA1
%
Total
UFA2
%
UFA/SFA Total
MUFA3
%
Total
PUFA4
%
PUFA/MUFA MUFA/SFA
C 44.82 46.41 1.04 46.15 0.26 0.006 1.030
T1 43.4 42.72 0.98 42.12 0.6 0.014 0.971
T2 38.266 39.21 1.02 38.42 0.79 0.021 1.004
T3 37.26 37.28 1.00 36.39 0.89 0.024 0.977 1 SFA – saturated fatty acids; 2 MUFA – monounsaturated fatty acids; 3 PUFA – polyunsaturated fatty acids.
On the other hand there were significant differences (P<0.01) for palmitoleic, steric,
linoleic and linolinleic acids. Lauric acid have higher value in group T1 followed by group C
.Myristic in group T3 was higher value followed by group control .This is may be attribute for
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process of liver to convert to cholesterol. Palmitic nevertheless insignificant but mathematical
have high value in group C because of SF utilization in this diet of group. Steric was high
light significant in group C which used paced fat ,on the other hand for oleic acid was higher
value in group T3 due to mixing differs type and level of USF. Linoleic acid have roll for
combination of LDL in the liver .high level was in group C .On the other hand for linolenic
which have role for combination of HDL was high value in group T3 which mixing
proportion more of USF.Arachidic acid insignificant where there high value in T1. On other
side arachidonic and behenic was in significant but high value was in group T3 and T2
respectively.These results agree with data obtain by Hulan et al. (1983).
CONCLUSION
It is found that amino acids profile changed in the liver by addition of those mixing
different type and level fat to improve the quality of the liver in the point view of human
health and well being, also increae of essential some amino acids like syctine acids by packed
fat . There were opposite relationship between levels of saturated fatty acids and proportion of
amino acids in liver chicks’
Acknowledgments: This work was financially supported by the Grant Agency of the Slovak
Ministry of Education and the Slovak Academy of Sciences under VEGA (Project n.
1/0662/11). To the poultry farm VľGLAŠ workers, Much thanks for the team of our departments
analyser really you doing well.
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